# Sketch - A Python-based interactive drawing program
# Copyright (C) 1997 -- 2003, 2005 by Bernhard Herzog
# Some code for Text elements contributed by Paul Giotta (2002)
#
# This library is free software; you can redistribute it and/or
# modify it under the terms of the GNU Library General Public
# License as published by the Free Software Foundation; either
# version 2 of the License, or (at your option) any later version.
#
# This library is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
# Library General Public License for more details.
#
# You should have received a copy of the GNU Library General Public
# License along with this library; if not, write to the Free Software
# Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307  USA

###Sketch Config
#type = Import
#class_name = 'SVGLoader'
#rx_magic = '.*\\<(\\?xml|svg)'
#tk_file_type = ('Scalable Vector Graphics (SVG)', ('.svg', '.xml'))
format_name = 'SVG'
#unload = 1
###End

from types import StringType
from math import pi, tan
import os, sys
import re
from string import strip, split, atoi, lower
import string
import operator

import streamfilter

from Sketch import Document, Layer, CreatePath, ContSmooth, \
     SolidPattern, EmptyPattern, LinearGradient, RadialGradient,\
     CreateRGBColor, CreateCMYKColor, MultiGradient, \
     Trafo, Translation, Rotation, Scale, Point, Polar, \
     StandardColors, GetFont, PathText, SimpleText, const, UnionRects, \
     Bezier, Line, load_image, skread

from Sketch.warn import INTERNAL, USER, warn_tb

from Sketch.load import GenericLoader, EmptyCompositeError

from Sketch.Graphics import text, properties

try:
    from xml.sax import saxlib, saxexts
except ImportError:
    warn_tb(USER, "The Python xml package has to be installed for the svg "
            "import filter.\n"
            "See the README for more information.")
    raise

# beginning with Python 2.0, the XML modules return Unicode strings,
# while for older versions they're 'normal' 8-bit strings. Provide some
# functions to make this code work with both string types.

def as_latin1(s):
    # convert the string s to iso-latin-1 if it's a unicode string
    encode = getattr(s, "encode", None)
    if encode is not None:
        s = encode("iso-8859-1", "replace")
    return s


# Conversion factors to convert standard CSS/SVG units to userspace
# units.
factors = {'pt': 1.0, 'px': 1.0, 'in': 72.0,
           'cm': 72.0 / 2.54, 'mm': 7.20 / 2.54}

degrees = pi / 180.0


def csscolor(str):
    str = strip(str)
    if str[0] == '#':
        if len(str) == 7:
            r = atoi(str[1:3], 16) / 255.0
            g = atoi(str[3:5], 16) / 255.0
            b = atoi(str[5:7], 16) / 255.0
        elif len(str) == 4:
            # According to the CSS rules a single HEX digit is to be
            # treated as a repetition of the digit, so that for a digit
            # d the value is (16 * d + d) / 255.0 which is equal to d / 15.0
            r = atoi(str[1], 16) / 15.0
            g = atoi(str[2], 16) / 15.0
            b = atoi(str[3], 16) / 15.0
        color = CreateRGBColor(r, g, b)
    elif namedcolors.has_key(str):
        color = namedcolors[str]
    else:
        color = StandardColors.black
    return color


namedcolors = {
    'aliceblue': csscolor('#f0f8ff'),
    'antiquewhite': csscolor('#faebd7'),
    'aqua': csscolor('#00ffff'),
    'aquamarine': csscolor('#7fffd4'),
    'azure': csscolor('#f0ffff'),
    'beige': csscolor('#f5f5dc'),
    'bisque': csscolor('#ffe4c4'),
    'black': csscolor('#000000'),
    'blanchedalmond': csscolor('#ffebcd'),
    'blue': csscolor('#0000ff'),
    'blueviolet': csscolor('#8a2be2'),
    'brown': csscolor('#a52a2a'),
    'burlywood': csscolor('#deb887'),
    'cadetblue': csscolor('#5f9ea0'),
    'chartreuse': csscolor('#7fff00'),
    'chocolate': csscolor('#d2691e'),
    'coral': csscolor('#ff7f50'),
    'cornflowerblue': csscolor('#6495ed'),
    'cornsilk': csscolor('#fff8dc'),
    'crimson': csscolor('#dc143c'),
    'cyan': csscolor('#00ffff'),
    'darkblue': csscolor('#00008b'),
    'darkcyan': csscolor('#008b8b'),
    'darkgoldenrod': csscolor('#b8860b'),
    'darkgray': csscolor('#a9a9a9'),
    'darkgreen': csscolor('#006400'),
    'darkgrey': csscolor('#a9a9a9'),
    'darkkhaki': csscolor('#bdb76b'),
    'darkmagenta': csscolor('#8b008b'),
    'darkolivegreen': csscolor('#556b2f'),
    'darkorange': csscolor('#ff8c00'),
    'darkorchid': csscolor('#9932cc'),
    'darkred': csscolor('#8b0000'),
    'darksalmon': csscolor('#e9967a'),
    'darkseagreen': csscolor('#8fbc8f'),
    'darkslateblue': csscolor('#483d8b'),
    'darkslategray': csscolor('#2f4f4f'),
    'darkslategrey': csscolor('#2f4f4f'),
    'darkturquoise': csscolor('#00ced1'),
    'darkviolet': csscolor('#9400d3'),
    'deeppink': csscolor('#ff1493'),
    'deepskyblue': csscolor('#00bfff'),
    'dimgray': csscolor('#696969'),
    'dimgrey': csscolor('#696969'),
    'dodgerblue': csscolor('#1e90ff'),
    'firebrick': csscolor('#b22222'),
    'floralwhite': csscolor('#fffaf0'),
    'forestgreen': csscolor('#228b22'),
    'fuchsia': csscolor('#ff00ff'),
    'gainsboro': csscolor('#dcdcdc'),
    'ghostwhite': csscolor('#f8f8ff'),
    'gold': csscolor('#ffd700'),
    'goldenrod': csscolor('#daa520'),
    'gray': csscolor('#808080'),
    'green': csscolor('#008000'),
    'greenyellow': csscolor('#adff2f'),
    'grey': csscolor('#808080'),
    'honeydew': csscolor('#f0fff0'),
    'hotpink': csscolor('#ff69b4'),
    'indianred': csscolor('#cd5c5c'),
    'indigo': csscolor('#4b0082'),
    'ivory': csscolor('#fffff0'),
    'khaki': csscolor('#f0e68c'),
    'lavender': csscolor('#e6e6fa'),
    'lavenderblush': csscolor('#fff0f5'),
    'lawngreen': csscolor('#7cfc00'),
    'lemonchiffon': csscolor('#fffacd'),
    'lightblue': csscolor('#add8e6'),
    'lightcoral': csscolor('#f08080'),
    'lightcyan': csscolor('#e0ffff'),
    'lightgoldenrodyellow': csscolor('#fafad2'),
    'lightgray': csscolor('#d3d3d3'),
    'lightgreen': csscolor('#90ee90'),
    'lightgrey': csscolor('#d3d3d3'),
    'lightpink': csscolor('#ffb6c1'),
    'lightsalmon': csscolor('#ffa07a'),
    'lightseagreen': csscolor('#20b2aa'),
    'lightskyblue': csscolor('#87cefa'),
    'lightslategray': csscolor('#778899'),
    'lightslategrey': csscolor('#778899'),
    'lightsteelblue': csscolor('#b0c4de'),
    'lightyellow': csscolor('#ffffe0'),
    'lime': csscolor('#00ff00'),
    'limegreen': csscolor('#32cd32'),
    'linen': csscolor('#faf0e6'),
    'magenta': csscolor('#ff00ff'),
    'maroon': csscolor('#800000'),
    'mediumaquamarine': csscolor('#66cdaa'),
    'mediumblue': csscolor('#0000cd'),
    'mediumorchid': csscolor('#ba55d3'),
    'mediumpurple': csscolor('#9370db'),
    'mediumseagreen': csscolor('#3cb371'),
    'mediumslateblue': csscolor('#7b68ee'),
    'mediumspringgreen': csscolor('#00fa9a'),
    'mediumturquoise': csscolor('#48d1cc'),
    'mediumvioletred': csscolor('#c71585'),
    'midnightblue': csscolor('#191970'),
    'mintcream': csscolor('#f5fffa'),
    'mistyrose': csscolor('#ffe4e1'),
    'moccasin': csscolor('#ffe4b5'),
    'navajowhite': csscolor('#ffdead'),
    'navy': csscolor('#000080'),
    'oldlace': csscolor('#fdf5e6'),
    'olive': csscolor('#808000'),
    'olivedrab': csscolor('#6b8e23'),
    'orange': csscolor('#ffa500'),
    'orangered': csscolor('#ff4500'),
    'orchid': csscolor('#da70d6'),
    'palegoldenrod': csscolor('#eee8aa'),
    'palegreen': csscolor('#98fb98'),
    'paleturquoise': csscolor('#afeeee'),
    'palevioletred': csscolor('#db7093'),
    'papayawhip': csscolor('#ffefd5'),
    'peachpuff': csscolor('#ffdab9'),
    'peru': csscolor('#cd853f'),
    'pink': csscolor('#ffc0cb'),
    'plum': csscolor('#dda0dd'),
    'powderblue': csscolor('#b0e0e6'),
    'purple': csscolor('#800080'),
    'red': csscolor('#ff0000'),
    'rosybrown': csscolor('#bc8f8f'),
    'royalblue': csscolor('#4169e1'),
    'saddlebrown': csscolor('#8b4513'),
    'salmon': csscolor('#fa8072'),
    'sandybrown': csscolor('#f4a460'),
    'seagreen': csscolor('#2e8b57'),
    'seashell': csscolor('#fff5ee'),
    'sienna': csscolor('#a0522d'),
    'silver': csscolor('#c0c0c0'),
    'skyblue': csscolor('#87ceeb'),
    'slateblue': csscolor('#6a5acd'),
    'slategray': csscolor('#708090'),
    'slategrey': csscolor('#708090'),
    'snow': csscolor('#fffafa'),
    'springgreen': csscolor('#00ff7f'),
    'steelblue': csscolor('#4682b4'),
    'tan': csscolor('#d2b48c'),
    'teal': csscolor('#008080'),
    'thistle': csscolor('#d8bfd8'),
    'tomato': csscolor('#ff6347'),
    'turquoise': csscolor('#40e0d0'),
    'violet': csscolor('#ee82ee'),
    'wheat': csscolor('#f5deb3'),
    'white': csscolor('#ffffff'),
    'whitesmoke': csscolor('#f5f5f5'),
    'yellow': csscolor('#ffff00'),
    'yellowgreen': csscolor('#9acd32'),
}

join = {'miter': const.JoinMiter,
        'round': const.JoinRound,
        'bevel': const.JoinBevel}
cap = {'butt': const.CapButt,
       'round': const.CapRound,
       'square': const.CapProjecting}

commatospace = string.maketrans(',', ' ')

rx_command = re.compile(r'[a-df-zA-DF-Z]((\s*[-0-9.e]+)*)\s*')
rx_trafo = re.compile(r'\s*([a-zA-Z]+)\(([^)]*)\)')


class SVGHandler(saxlib.HandlerBase):

    dispatch_start = {'svg': 'initsvg',
                      'g': 'begin_group',
                      'circle': 'circle',
                      'ellipse': 'ellipse',
                      'rect': 'rect',
                      'polyline': 'polyline',
                      'polygon': 'polygon',
                      'path':   'begin_path',
                      'text':   'begin_text',
                      'image':   'image',
                      'data':   'data',
                      'use':   'use',
                      'defs':   'begin_defs',
                      }
    dispatch_end = {'g': 'end_group',
                    'path': 'end_path',
                    'defs': 'end_defs',
                    'text': 'end_text'
                    }

    def __init__(self, loader):
        self.loader = loader
        self.trafo = self.basetrafo = Trafo()
        self.state_stack = ()
        self.style = loader.style.Copy()
        self.style.line_pattern = EmptyPattern
        self.style.fill_pattern = SolidPattern(StandardColors.black)
        self.current_text = ""
        self.style.font = GetFont("Times-Roman")
        self.style.font_size = 12
        self.halign = text.ALIGN_LEFT
        self.named_objects = {}
        self.in_defs = 0
        self.paths = None
        self.path = None
        self.depth = 0
        self.indent = '    '

    def _print(self, *args):
        return
        if args:
            print self.depth * self.indent + args[0],
        for s in args[1:]:
            print s,
        print

    def parse_transform(self, trafo_string):
        trafo = self.trafo
        #print trafo
        trafo_string = as_latin1(trafo_string)
        while trafo_string:
            #print trafo_string
            match = rx_trafo.match(trafo_string)
            if match:
                function = match.group(1)
                args = string.translate(match.group(2), commatospace)
                args = map(float, split(args))
                trafo_string = trafo_string[match.end(0):]
                if function == 'matrix':
                    trafo = trafo(apply(Trafo, tuple(args)))
                elif function == 'scale':
                    trafo = trafo(Scale(args[0]))
                elif function == 'translate':
                    dx, dy = args
                    trafo = trafo(Translation(dx, dy))
                elif function == 'rotate':
                    trafo = trafo(Rotation(args[0] * degrees))
                elif function == 'skewX':
                    trafo = trafo(Trafo(1, 0, tan(args[0] * degrees), 1, 0, 0))
                elif function == 'skewY':
                    trafo = trafo(Trafo(1, tan(args[0] * degrees), 0, 1, 0, 0))
            else:
                trafo_string = ''
        #print trafo
        self.trafo = trafo

    def startElement(self, name, attrs):
        self._print('(', name)
        for key, value in attrs.items():
            self._print('  -', key, `value`)
        self.depth = self.depth + 1
        self.push_state()
        if attrs.has_key('transform'):
            self.parse_transform(attrs['transform'])
        self._print("applied transormation", self.trafo)
        method = self.dispatch_start.get(name)
        if method is not None:
            getattr(self, method)(attrs)

    def endElement(self, name):
        self.depth = self.depth - 1
        self._print(')', name)
        method = self.dispatch_end.get(name)
        if method is not None:
            getattr(self, method)()
        self.pop_state()

    def characters(self, ch, start, length):
        self.current_text = self.current_text + as_latin1(ch)

    def error(self, exception):
        print 'error', exception

    def fatalError(self, exception):
        print 'fatalError', exception

    def warning(self, exception):
        print 'warning', exception

    def initsvg(self, attrs):
        width = self.user_length(attrs.get('width', '100%'))
        height = self.user_length(attrs.get('height', '100%'))
        self._print('initsvg', width, height)
        self.trafo = Trafo(1, 0, 0, -1, 0, height)
        self.basetrafo = self.trafo
        # evaluate viewBox
        # FIXME: Handle preserveAspectRatio as well
        viewbox = attrs.get("viewBox", "")
        if viewbox:
            vx, vy, vwidth, vheight = map(float, split(viewbox))
            t = Scale(width / vwidth, height / vheight)
            t = t(Translation(-vx, -vy))
            self.trafo = self.trafo(t)
        self._print("basetrafo", self.basetrafo)

    def parse_style(self, style):
        parts = filter(None, map(strip, split(style, ';')))
        for part in parts:
            key, val = map(strip, split(part, ':', 1))
            self._print('style', key, val)

            # only try to parse the value if it's not empty
            if val:
                self.try_add_style(key, val)
            else:
                # FIXME: we should probably print a message or something
                pass

    def try_add_style(self,key,val):
        if key == 'fill':
            if val == 'none':
                self.style.fill_pattern = EmptyPattern
            else:
                color = csscolor(val)
                self._print('fill', color)
                self.style.fill_pattern = SolidPattern(color)
        elif key == 'stroke':
            if val == 'none':
                self.style.line_pattern = EmptyPattern
            else:
                color = csscolor(val)
                self._print('stroke', color)
                self.style.line_pattern = SolidPattern(color)
        elif key == 'stroke-width':
            width = self.user_length(val)
            # Multiply the width with a value taken from the
            # transformation matrix because so far transforming an
            # object in Sketch does not affect the stroke width in any
            # way. Thus we have to do that explicitly here.
            # FIXME: using m11 is not really the best approach but in
            # many cases better than using the width as is.
            width = self.trafo.m11 * width
            self._print('width', width)
            self.style.line_width = width
        elif key == 'stroke-linejoin':
            self.style.line_join = join[val]
        elif key == 'stroke-linecap':
            self.style.line_cap = cap[val]
        elif key == 'font-family':
            try:
                # convert val to 8bit string.
                self.style.font = GetFont(str(val))
            except UnicodeError:
                # If it's not ASCII we probably won't have the font, so
                # use the default one.
                # FIXME: Give a warning
                pass
        elif key == 'font-size':
            self.style.font_size = self.user_length(val)
            ####self.style.font_size = float(val)
        elif key == 'text-anchor':
            if val=='start':
                self.halign = text.ALIGN_LEFT
            elif val == 'middle':
                self.halign = text.ALIGN_CENTER
            elif val == 'end':
                self.halign = text.ALIGN_RIGHT

    def set_loader_style(self, allow_font = 0):
        # Copy self.style to loader.
        # If allow_font is false (the default) do not copy the font
        # properties.
        property_types = properties.property_types
        style = self.style.Copy()
        if not allow_font:
            for name in style.__dict__.keys():
                if property_types.get(name)==properties.FontProperty:
                    delattr(style, name)
        self.loader.style = style

    def push_state(self):
        self.state_stack = self.style, self.trafo, self.state_stack
        self.style = self.style.Copy()

    def pop_state(self):
        self.style, self.trafo, self.state_stack = self.state_stack

    def user_length(self, str):
        # interpret string as a length and return the appropriate value
        # user coordinates
        str = strip(str)
        factor = factors.get(str[-2:])
        if factor is not None:
            str = str[:-2]
        elif str[-1] == '%':
            # FIXME: this case depends on the width/height attrs of the
            # SVG element
            str = str[:-1]
            factor = 1.0
        else:
            factor = 1.0
        return float(str) * factor

    def user_point(self, x, y):
        # Return the point described by the SVG coordinates x and y as
        # an SKPoint object in user coordinates. x and y are expected to
        # be strings.
        x = strip(x)
        y = strip(y)

        # extract the units from the coordinate values if any and
        # determine the appropriate factor to convert those units to
        # user space units.
        xunit = x[-2:]
        factor = factors.get(xunit)
        if factor is not None:
            x = x[:-2]
        elif x[-1] == '%':
            # XXX this is wrong
            x = x[:-1]
            xunit = '%'
            factor = 1
        else:
            xunit = ''
            factor = 1.0
        x = float(x) * factor

        yunit = y[-2:]
        factor = factors.get(yunit)
        if factor is not None:
            y = y[:-2]
        elif y[-1] == '%':
            y = y[:-1]
            yunit = '%'
            factor = 1.0
        else:
            yunit = ''
            factor = 1.0
        y = float(y) * factor

        return Point(x, y)


    def point(self, x, y, relative = 0):
        # Return the point described by the SVG coordinates x and y as
        # an SKPoint object in absolute, i.e. document coordinates. x
        # and y are expected to be strings. If relative is true, they're
        # relative coordinates.
        x, y = self.user_point(x, y)

        if relative:
            p = self.trafo.DTransform(x, y)
        else:
            p = self.trafo(x, y)
        return p


    def circle(self, attrs):
        if self.in_defs:
            id = attrs.get('id', '')
            if id:
                self.named_objects[id] = ('object', 'circle', attrs)
            return
        if attrs.has_key('cx'):
            x = attrs['cx']
        else:
            x = '0'
        if attrs.has_key('cy'):
            y = attrs['cy']
        else:
            y = '0'
        x, y = self.point(x, y)
        r = self.point(attrs['r'], '0', relative = 1).x
        t = Trafo(r, 0, 0, r, x, y)
        self._print('circle', t)
        style = attrs.get('style', '')
        if style:
            self.parse_style(style)
        self.set_loader_style()
        apply(self.loader.ellipse, t.coeff())


    def ellipse(self, attrs):
        if self.in_defs:
            id = attrs.get('id', '')
            if id:
                self.named_objects[id] = ('object', 'ellipse', attrs)
            return
        if attrs.has_key('cx'):
            x = attrs['cx']
        else:
            x = '0'
        if attrs.has_key('cy'):
            y = attrs['cy']
        else:
            y = '0'
        x, y = self.point(x, y)
        rx, ry = self.point(attrs['rx'], attrs['ry'], relative = 1)
        t = Trafo(rx, 0, 0, ry, x, y)
        self._print('ellipse', t)
        style = attrs.get('style', '')
        if style:
            self.parse_style(style)
        self.set_loader_style()
        apply(self.loader.ellipse, t.coeff())

    def rect(self, attrs):
        #print 'rect', attrs.map
        if self.in_defs:
            id = attrs.get('id', '')
            if id:
                self.named_objects[id] = ('object', 'rect', attrs)
            return
        if attrs.has_key('x'):
            x = attrs['x']
        else:
            x = '0'
        if attrs.has_key('y'):
            y = attrs['y']
        else:
            y = '0'
        x, y = self.point(x, y)
        wx, wy = self.point(attrs['width'], "0", relative = 1)
        hx, hy = self.point("0", attrs['height'], relative = 1)
        t = Trafo(wx, wy, hx, hy, x, y)
        self._print('rect', t)
        style = attrs.get('style', '')
        if style:
            self.parse_style(style)
        self.set_loader_style()
        apply(self.loader.rectangle, t.coeff())

    def polyline(self, attrs):
        if self.in_defs:
            id = attrs.get('id', '')
            if id:
                self.named_objects[id] = ('object', 'polyline', attrs)
            return
        points = as_latin1(attrs['points'])
        points = string.translate(points, commatospace)
        points = split(points)
        path = CreatePath()
        point = self.point
        for i in range(0, len(points), 2):
            path.AppendLine(point(points[i], points[i + 1]))
        style = attrs.get('style', '')
        if style:
            self.parse_style(style)
        self.set_loader_style()
        self.loader.bezier(paths = (path,))

    def polygon(self, attrs):
        if self.in_defs:
            id = attrs.get('id', '')
            if id:
                self.named_objects[id] = ('object', 'polygon', attrs)
            return
        points = as_latin1(attrs['points'])
        points = string.translate(points, commatospace)
        points = split(points)
        path = CreatePath()
        point = self.point
        for i in range(0, len(points), 2):
            path.AppendLine(point(points[i], points[i + 1]))
        path.AppendLine(path.Node(0))
        path.ClosePath()
        style = attrs.get('style', '')
        if style:
            self.parse_style(style)
        self.set_loader_style()
        self.loader.bezier(paths = (path,))

    def parse_path(self, str):
        paths = self.paths
        path = self.path
        trafo = self.trafo
        str = strip(string.translate(as_latin1(str), commatospace))
        last_quad = None
        last_cmd = cmd = None
        f13 = 1.0 / 3.0; f23 = 2.0 / 3.0
        #print '*', str
        while 1:
            match = rx_command.match(str)
            #print match
            if match:
                last_cmd = cmd
                cmd = str[0]
                str = str[match.end():]
                #print '*', str
                points = match.group(1)
                #print '**', points
                if points:
                    # use tokenize_line to parse the arguments so that
                    # we deal with signed numbers following another
                    # number without intervening whitespace other
                    # characters properls.
                    # FIXME: tokenize_line works but is not the best way
                    # to do it because it accepts input that wouldn't be
                    # valid here.
                    points = filter(operator.isNumberType,
                                    skread.tokenize_line(points))
                #print cmd, points
                if cmd in 'mM':
                    path = CreatePath()
                    paths.append(path)
                    if cmd == 'M' or len(paths) == 1:
                        path.AppendLine(trafo(points[0], points[1]))
                    else:
                        p = trafo.DTransform(points[0], points[1])
                        path.AppendLine(paths[-2].Node(-1) + p)
                    if len(points) > 2:
                        if cmd == 'm':
                            for i in range(2, len(points), 2):
                                p = trafo.DTransform(points[i], points[i + 1])
                                path.AppendLine(path.Node(-1) + p)
                        else:
                            for i in range(2, len(points), 2):
                                path.AppendLine(trafo(points[i], points[i+1]))
                elif cmd == 'l':
                    for i in range(0, len(points), 2):
                        p = trafo.DTransform(points[i], points[i + 1])
                        path.AppendLine(path.Node(-1) + p)
                elif cmd == 'L':
                    for i in range(0, len(points), 2):
                        path.AppendLine(trafo(points[i], points[i+1]))
                elif cmd =='H':
                    for num in points:
                        path.AppendLine(Point(num, path.Node(-1).y))
                elif cmd =='h':
                    for num in points:
                        x, y = path.Node(-1)
                        dx, dy = trafo.DTransform(num, 0)
                        path.AppendLine(Point(x + dx, y + dy))
                elif cmd =='V':
                    for num in points:
                        path.AppendLine(Point(path.Node(-1).x, num))
                elif cmd =='v':
                    for num in points:
                        x, y = path.Node(-1)
                        dx, dy = trafo.DTransform(0, num)
                        path.AppendLine(Point(x + dx, y + dy))
                elif cmd == 'C':
                    if len(points) % 6 != 0:
                        self.loader.add_message("number of parameters of 'C'"\
                                                "must be multiple of 6")
                    else:
                        for i in range(0, len(points), 6):
                            p1 = trafo(points[i], points[i + 1])
                            p2 = trafo(points[i + 2], points[i + 3])
                            p3 = trafo(points[i + 4], points[i + 5])
                            path.AppendBezier(p1, p2, p3)
                elif cmd == 'c':
                    if len(points) % 6 != 0:
                        self.loader.add_message("number of parameters of 'c'"\
                                                "must be multiple of 6")
                    else:
                        for i in range(0, len(points), 6):
                            p = path.Node(-1)
                            p1 = p + trafo.DTransform(points[i], points[i + 1])
                            p2 = p + trafo.DTransform(points[i+2], points[i+3])
                            p3 = p + trafo.DTransform(points[i+4], points[i+5])
                            path.AppendBezier(p1, p2, p3)
                elif cmd == 'S':
                    if len(points) % 4 != 0:
                        self.loader.add_message("number of parameters of 'S'"\
                                                "must be multiple of 4")
                    else:
                        for i in range(0, len(points), 4):
                            type, controls, p, cont = path.Segment(-1)
                            if type == Bezier:
                                q = controls[1]
                            else:
                                q = p
                            p1 = 2 * p - q
                            p2 = trafo(points[i], points[i + 1])
                            p3 = trafo(points[i + 2], points[i + 3])
                            path.AppendBezier(p1, p2, p3)
                elif cmd == 's':
                    if len(points) % 4 != 0:
                        self.loader.add_message("number of parameters of 's'"\
                                                "must be multiple of 4")
                    else:
                        for i in range(0, len(points), 4):
                            type, controls, p, cont = path.Segment(-1)
                            if type == Bezier:
                                q = controls[1]
                            else:
                                q = p
                            p1 = 2 * p - q
                            p2 = p + trafo.DTransform(points[i], points[i + 1])
                            p3 = p + trafo.DTransform(points[i+2], points[i+3])
                            path.AppendBezier(p1, p2, p3)
                elif cmd == 'Q':
                    if len(points) % 4 != 0:
                        self.loader.add_message("number of parameters of 'Q'"\
                                                "must be multiple of 4")
                    else:
                        for i in range(0, len(points), 4):
                            q = trafo(points[i], points[i + 1])
                            p3 = trafo(points[i + 2], points[i + 3])
                            p1 = f13 * path.Node(-1) + f23 * q
                            p2 = f13 * p3 + f23 * q
                            path.AppendBezier(p1, p2, p3)
                            last_quad = q
                elif cmd == 'q':
                    if len(points) % 4 != 0:
                        self.loader.add_message("number of parameters of 'q'"\
                                                "must be multiple of 4")
                    else:
                        for i in range(0, len(points), 4):
                            p = path.Node(-1)
                            q = p + trafo.DTransform(points[i], points[i + 1])
                            p3 = p + trafo.DTransform(points[i+2], points[i+3])
                            p1 = f13 * p + f23 * q
                            p2 = f13 * p3 + f23 * q
                            path.AppendBezier(p1, p2, p3)
                            last_quad = q
                elif cmd == 'T':
                    if len(points) % 2 != 0:
                        self.loader.add_message("number of parameters of 'T'"\
                                                "must be multiple of 4")
                    else:
                        if last_cmd not in 'QqTt' or last_quad is None:
                            last_quad = path.Node(-1)
                        for i in range(0, len(points), 2):
                            p = path.Node(-1)
                            q = 2 * p - last_quad
                            p3 = trafo(points[i], points[i + 1])
                            p1 = f13 * p + f23 * q
                            p2 = f13 * p3 + f23 * q
                            path.AppendBezier(p1, p2, p3)
                            last_quad = q
                elif cmd == 't':
                    if len(points) % 2 != 0:
                        self.loader.add_message("number of parameters of 't'"\
                                                "must be multiple of 4")
                    else:
                        if last_cmd not in 'QqTt' or last_quad is None:
                            last_quad = path.Node(-1)
                        for i in range(0, len(points), 2):
                            p = path.Node(-1)
                            q = 2 * p - last_quad
                            p3 = p + trafo.DTransform(points[i], points[i + 1])
                            p1 = f13 * p + f23 * q
                            p2 = f13 * p3 + f23 * q
                            path.AppendBezier(p1, p2, p3)
                            last_quad = q

                elif cmd in 'zZ':
                    path.AppendLine(path.Node(0))
                    path.ClosePath()
            else:
                break
        self.path = path

    def begin_path(self, attrs):
        if self.in_defs:
            id = attrs.get('id', '')
            if id:
                self.named_objects[id] = ('object', 'path', attrs)
            return
        self.paths = []
        self.path = None
        self.parse_path(attrs['d'])
        style = attrs.get('style', '')
        if style:
            self.parse_style(style)
        self.set_loader_style()

    def end_path(self):
        if self.in_defs:
            return
        self.loader.bezier(paths = tuple(self.paths))
        self.paths = None

    def image(self, attrs):
        if self.in_defs:
            id = attrs.get('id', '')
            if id:
                self.named_objects[id] = ('object', 'image', attrs)
            return
        href = as_latin1(attrs['xlink:href'])
        image = load_image(os.path.join(self.loader.directory, href)).image
        if attrs.has_key('x'):
            x = attrs['x']
        else:
            x = '0'
        if attrs.has_key('y'):
            y = attrs['y']
        else:
            y = '0'
        x, y = self.user_point(x, y)

        width = self.user_length(attrs['width'])
        scalex =  width / image.size[0]

        height = self.user_length(attrs['height']) 
        scaley = -height / image.size[1]

        style = attrs.get('style', '')
        if style:
            self.parse_style(style)
        self.set_loader_style()
        t = self.trafo(Trafo(scalex, 0, 0, scaley, x, y + height))
        self._print('image', t)
        self.loader.image(image, t)

    def begin_text(self, attrs):
        if self.in_defs:
            id = attrs.get('id', '')
            if id:
                self.named_objects[id] = ('object', 'text', attrs)
            return

        # parse the presentation attributes if any.
        # FIXME: this has to be implemented for the other elements that
        # can have presentation attributes as well.
        for key,value in attrs.items():
            self.try_add_style(key,value)

        if attrs.has_key('x'):
            x = attrs['x']
        else:
            x = '0'
        if attrs.has_key('y'):
            y = attrs['y']
        else:
            y = '0'
        x, y = self.user_point(x, y)
        self.text_trafo = self.trafo(Trafo(1, 0, 0, -1, x, y))
        self._print('text', self.text_trafo)
        style = attrs.get('style', '')
        if style:
            self.parse_style(style)
        self.set_loader_style(allow_font = 1)
        self.current_text=''

    def end_text(self):
        self.loader.simple_text(strip(self.current_text), self.text_trafo,
                                halign = self.halign)

    def data(self, attrs):
        pass

    def begin_group(self, attrs):
        style = attrs.get('style', '')
        if style:
            self.parse_style(style)
        self.loader.begin_group()

    def end_group(self):
        try:
            self.loader.end_group()
        except EmptyCompositeError:
            pass

    def use(self, attrs):
        #print 'use', attrs.map
        if attrs.has_key('xlink:href'):
            name = attrs['xlink:href']
        else:
            name = attrs.get('href', '<none>')
        if name:
            data = self.named_objects.get(name[1:])
            if data[0] == 'object':
                if attrs.has_key('style'):
                    self.parse_style(attrs['style'])
                self.startElement(data[1], data[2])
                self.endElement(data[1])


    def begin_defs(self, attrs):
        self.in_defs = 1

    def end_defs(self):
        self.in_defs = 0

class SVGLoader(GenericLoader):

    format_name = format_name

    def __init__(self, file, filename, match):
        GenericLoader.__init__(self, file, filename, match)
        if self.filename:
            self.directory = os.path.split(filename)[0]
        else:
            self.directory = ''

    def __del__(self):
        pass

    def Load(self):
        try:
            self.document()
            self.layer()

            parser = saxexts.make_parser()
            parser.setDocumentHandler(SVGHandler(self))
            try:
                self.file.seek(0)
                file = self.file
            except:
                file = streamfilter.StringDecode(self.match.string, self.file)
            parser.parseFile(file)

            self.end_all()
            self.object.load_Completed()
            return self.object
        except:
            warn_tb('INTERNAL')
            raise
